Università degli Studi di Pisa Dipartimento di Fisica E. Fermi Giulia De Bonis I.N.F.N. - Pisa
Outlook Introduction Neutrino Astronomy: Motivations, Neutrino Production, Expected Fluxes Submarine Observatories: Cherenkov Telescopes The pilot projects: ANTARES, NEMO, NESTOR The South Pole: IceCube The Mediterranean Sea a full-coverage of the Sky The KM3NeT Consortium KM3NeT Design Study - Conceptual Design Report (CDR) Design Goals Detector Layout and Expected Detector Performances Technical Implementations: OMs, DAQ, Data/Power Transmission, Deployment Site Investigations Associated Sciences Technical Design Report (TDR) Preparatory Phase (PP) Summary and Perspectives - KM3Net Timeline Giulia De Bonis 2
Neutrino Astronomy a Multi-Messenger Approach in the Astrophysical Research Weakly-interacting neutrinos retain directional information - a strong motivation for Neutrino Astronomy Protons/nuclei are deflected and/or absorbed Astrophysics UHECνs as a diagnostic of astrophys. processes - astrophysical sources, acceleration engines neutrino observations can discriminate between different acceleration mechanisms (hadronic/e.m.) - cosmic rays propagation GZK cut-off Particle Physics Electromagnetic radiation (γ-rays) is absorbed - Neutrino Physics - σνn at E>Eacc. - NewPhysics beyond SM (strongly interacting νs) UHEνs Production Cosmogenic neutrino flux Cosmology - EHECν absorption on CνB - top-down models (TD, DM and WIMPs) Weak interaction at the same time a great opportunity for discoveries and a gigantic obstacle for detection Giulia De Bonis the Challenge of Neutrino Detection
Neutrino Fluxes and Neutrino Detectors Optimal Sensitivity Energy Range for Underwater/Ice Cherenkov Telescopes 1TeV 10 PeV Flux @10 5 GeV ~ 3 10 5 GeV m 2 yr sr ~ 3 10 1 GeV km 2 yr sr Predicted neutrino fluxes are very LOW + weak interactions Earth s Opacity to up-going ν s Cubic kilometer scale detectors are required (1-4 and 6) AGN models; (5) GZK; (7) GRB; (8) topological defects [adapted from Learned and Mannheim,Annu. Rev. Nucl. Part. Sci. 50 (2000)] Giulia De Bonis Natural Target (ICE, WATER) DEPTH prevent atmo. µ contamination
High Energy Neutrino Detection Cherenkov Telescopes Cherenkov neutrino telescopes look for ultra-relativistic (β~1) muons produced in charged current neutrino interactions: refractive index of the medium (water or ice) n>1 light speed in the medium c/n < βc particle speed coherent emission of Cherenkov light Cherenkov angle: cosϕ = 1 in water: n~1.35 φ~ 43 nβ Detectors are made up as a regular grid of PMTs. The particle track direction can be reconstructed comparing time of arrivals of photons to the PMTs. Once that the muon track direction has be identified, pointing properties of the telescope are assured by the fact that at high energies the muon direction is almost collinear to the primary neutrino. simulation AMANDA/IceCube Baikal ANTARES, NEMO, NESTOR KM3NET
The South Pole and the Mediterranean Sea a full-sky coverage [ up-going ν s ] http://icecube.wisc.edu/ a northern emisphere neutrino observatory is a desideratum Giulia De Bonis 6
Mediterranean Sea The pilot projects NEMO ANTARES Giulia De Bonis NESTOR 7
ANTARES Completed in June 2008 data taking and analysis on going The largest (0.1 km 2 ) operating neutrino telescope in the Northern emisphere 12 strings 25 storeys per string 3 PMTs per storey Giulia De Bonis 8
NEMO multi-disciplinary investigations of the submarine environment development of technological solution (mechanics and electronics) Key-point of the proposal: compact (arms~10m) semi-rigid structure (tower) deployment based on the unfurling NEMO-Phase1 (2002-2006): realization and deployment of a mini-tower (4 storeys, 4 PMTs each) in the NEMO test-site (~2000m depth, 25km off Catania, Sicily) NEMO-Phase2 (ongoing): realization and deployment of a full NEMO in the Capo Passero site (3500, depth, 100km off-shore) status: 100km electro-optical cable deployed underwater; shore station infrastructure completed Giulia De Bonis 9
NESTOR Key-point of the proposal: extended rigid star-like structure suitable for a clustered detector layout MILESTONES 2002: deployment of a multidisciplinary (optical modules + environmental sensors) deep-sea station (4100m depth), cable-connected to shore (project LAERTIS) 2003: deployment of a test-floor (12 PMTs), ~1 month of data-taking and environment monitoring on-going activity: Delta-Berenike deployment platform Giulia De Bonis 10
towards the km3 The KM3NeT Consortium http://www.km3net.org/ THE GOAL connect people working in the field of high-energy neutrino telescopes share experiences gained with the pilot projects carry on a unique project for a cubic kilometer detector in the Mediterranean Sea Ireland UK France Spain Netherlands Germany Romania Italy Greece The full list of the institutes and university groups constituting the Consortium is available @KM3NeT web site Cyprus Giulia De Bonis 11
KM3NeT Timeline 2006: KM3NeT singled out by ESFRI (the European Strategy Forum on Research Infrastructures) to be included in the European Roadmap for Research Infrastructures. EU FP6 framework funding EU FP7 framework funding Giulia De Bonis 12
02/2006 12/2009 KM3NeT Design Study EU FP6 framework funding Design Study: development of a cost-effective design for a km3-deep-sea infrastructure housing a neutrino telescope and providing long-term access for deep-sea research. The multi-disciplinary activities of the KM3NeT Consortium are organized in working packages, covering all the main features in the design study of a neutrino submarine telescope; among them: physics analysis and simulation, to investigate the performance of different detector options; shore, sea-surface and deep-sea infrastructure, to carry on site-selection activity and to develop deployment and recovery procedures; design of the optical modules; design of the readout and data acquisition system; interactions with associated sciences, as biology, geology, oceanography. CDR (Conceptual Design Report) published in April 2008 TDR (Technical Design Report) by the of 2009 Giulia De Bonis 13
Neutrino Telescope Design Goal CDR Indications and Constraints instrumented volume > 1 km 3 lifetime > 10 yr without major mantainance construction and deployment < 4 yr budgetary constraint 200-250 M optimal sensitivity to neutrinos in the energy range 1 TeV 1 PeV angular resolution < 0.1 (Eν > 100 TeV) some technical requirements: - time resolution < 2ns (RMS) crucial for the track - position resolution < 40cm (RMS) reconstruction algorithms Giulia De Bonis 14
Detector Layout Intermediate E (1-100 TeV) good ang. Reso. (Point-Source Search) Low Energies (Dark Matter Search) Very High Energies poorer ang. reso. (GZK ν s ) Giulia De Bonis 15
Simulation Detector Performances reference detector homogeneous configuration 225 (15x15) detection units 37 storey each, 1 OMstorey 21 3-inch PMTs per OM Neutrino Effective Area 15.5m Detector Sensitivity 1km 3 instr. volume E ν [GeV] (different detector designs can provide similar performances ) Giulia De Bonis 16
Optical Modules standard OM (pilot projects) large-area (10 ) hemispherical PMT (bi-alkali) in a 17 glass sphere new concepts (under investigations) direction-sensitive OM with a focusing mirror system 2/3 large-area PMTs in a larger glass sphere (capsule) many (up to 40) 3 PMTs 1vs2 p.e. separat. directionality maximise photocatode area Giulia De Bonis 17
Data/Power Transmission power distribution through one or more junction boxes ~ 60kW total power on-shore electro-optical cable (standard telecommunications cable) data transport: Dense Wavelength Division Multiplexing (DWDM) on optical fibre all data to shore (data-flow= some 100Gb/s) on-shore triggering depends on detector layout and OM design Deployment accurate positioning easy access, efficient procedures ships (compact structures) / dedicated platform (Delta-Berenike) use of ROV / AUV progressive deployment has to take into account sea-floor cabling Giulia De Bonis 18
Site Investigation Extensive sea campaigns carried out at the candidate sites (i.e. where the three pilot projects are operating), in order to monitor: water optical properties: light transmission optical background: 40 K bioluminescence deep sea currents (and correlation with other params) sedimentation and bio-fouling L a (λ) abs. length L b (λ) scatt. length 1/L c (λ)=1/l a (λ)+1/l b (λ) att. length Toulon Capo Passero Pylos Together with political issue, results concerning the water quality influence the site selction Preparatory Phase (PP) Giulia political De Bonis convergence 19
Associated Sciences The KM3Net infrstructure will offer a unique opportunity for a multidisciplinary observatory in the abyss long-term real-time measurements in the deep sea: Oceanographic parameters (current velocity and direction) Environmental parameters (temperature, conductibility, salinity, pressure, natural optical noise from sea organisms) specialised instrumentation for seismology, gravimetry, radioactivity, geomagnetism, oceanography and geochemistry Associated sciences nodes will be independent (dedicated junction box) from the main installation of the neutrino telescope. The associated science infrastructure will be continually evolving: design goals include simple and cost effective upgrade of components. KM3NeT will become part of the ESONET Giulia De (European Bonis Seafloor Observatory Network) 20
03/2008 03/2011 EU FP7 framework funding next step: KM3NeT Preparatory Phase (PP) political and scientific convergence on the legal, governance, financial engineering and siting aspects construction of the KM3NeT infrastructure is foreseen to start after the three year preparatory phase (2011). Include quality control and risk analysis Giulia De Bonis 21
Summary and Perspectives KM3NeT Timeline Neutrinos are Welcome! EU FP6 framework funding EU FP7 framework funding Giulia De Bonis 22
back-up slides Giulia De Bonis 23
UHEν s Production: Acceleration (bottom-up model) Fermi engine (AGNs, SNRs) protons, confined by magnetic fields, are accelerated through repeated scattering by plasma shock front; collisions of trapped protons with ambient plasma produce γs and νs through pion photoproduction mechanism: ± π p + N, γ X + o π neutrinos γ rays E ν ~ 0.05 E p dn de 2 E [A. Ringwald] core of Galaxy NGC 4261 Hubble Space Telescope Giulia De Bonis
CR Propagation GZK cut-off [Greisen Zatsepin Kuzmin] The UHE CR horizon is limited by interactions with low energy background radiation Pion Photoproduction 0 p +π γγ Eγ ~ 10-4 ev (T~2.7 K) E th ~ 3 10 19 ev + n +π + µ +ν µ p + e + ν e + + ν µ + ν e e n CMBR ~ 400 cm -3 σ pγ ~ 100 µbarn λ pcmbr att = σ pγ 1 n CMBR <50 Mpc GZK NEUTRINOS (cosmogenic neutrino flux) Giulia De Bonis